Gradient amplifier with compensation for dead time and forward voltage

The invention claimed is: 1. A method for compensating non-linearities of a gradient amplifier for powering a gradient coil, the gradient amplifier comprising a controllable full bridge and an output filter, whereby the full bridge is controlled to provide a desired coil current, the method comprising: receiving a desired duty cycle of the gradient amplifier, measuring an input current and an output voltage of the output filter, evaluating a modulator duty cycle as a function of the desired duty cycle and the measured input current and the measured output voltage, and providing the modulator duty cycle to a modulator for controlling the full bridge, comprising: generating a three-dimensional look-up table, which provides the modulator duty cycle as a function of the desired duty cycle, the input current and the output voltage, including generating supporting points, which have a mixed logarithmically/linear distribution comprising generating a set of supporting points for positive values with a number of n logarithmically distributed main divisions and a number of 2 m linear subdivisions between each main division, where m is a set of bits following a most significant bit, and wherein the step of evaluating the modulator duty cycle comprises performing a look-up in the three-dimensional look-up table, the step of performing the look-up in the three-dimensional lookup-table comprises: determining an index value of the element in the three-dimensional look-up table by determining a logarithmic offset by evaluating a position of the most significant bit of the value to be looked-up and multiplying the position by 2 m , taking the value of the set of m bits following the most significant bit as linear offset, and providing a sum of the logarithmic offset and the linear offset as index value. 2. The method according to claim 1 , further comprising the step of generating an inverted three-dimensional look-up table, which provides the desired duty cycle as a function of the modulator duty cycle, the input current, and the output voltage, whereby the step of evaluating the modulator duty cycle further comprises performing a look-up of the desired duty cycle in the inverted three-dimensional lookup-table and determining the modulator duty cycle from the desired duty cycle according to the inverted three-dimensional look-up table. 3. The method according to claim 2 , wherein the step of determining the modulator duty cycle from the desired duty cycle according to the inverted three-dimensional look-up table comprises approximating of the modulator duty cycle using a bisection method. 4. The method according to claim 1 , wherein the step of evaluating the modulator duty cycle comprises performing an interpolation between supporting points of the three-dimensional look-up table. 5. The method according to claim 1 , further including: performing a linear interpolation between the supporting points of the three-dimensional look-up table, whereby a remainder following the set of m bits following the most significant bit defines the position of the value to be looked-up between adjacent supporting points. 6. The method according to claim 1 , wherein the step of generating the three-dimensional look-up table comprises determining supporting points of the three-dimensional look-up table by simulation or by mathematical calculation. 7. A non-transitory computer-readable medium carrying a set of instructions that controls a computer to perform the method according to claim 1 . 8. A method for compensating non-linearities of a gradient amplifier for powering a gradient coil, the gradient amplifier comprising a controllable full bridge and an output filter, whereby the full bridge is controlled to provide a desired coil current, the method comprising: receiving a desired duty cycle of the gradient amplifier, measuring an input current and an output voltage of the output filter, evaluating a modulator duty cycle as a function of the desired duty cycle and the measured input current and the measured output voltage, and providing the modulator duty cycle to a modulator for controlling the full bridge and comprising the step of generating a three-dimensional look-up table, which provides the modulator duty cycle as a function of the desired duty cycle, the input current and the output voltage, comprising generating supporting points, which have a mixed logarithmically/linear distribution comprising generating a set of supporting points equally distributed around zero with a number of 2n logarithmically distributed main divisions and a number of 2 m linear subdivisions between each main division, where m is a set of bits following a most significant bit, and wherein the step of evaluating the modulator duty cycle comprises performing a look-up in the three-dimensional look-up table, the step of performing the look-up in the three-dimensional lookup-table comprises: determining an index value of the element in the three-dimensional look-up table by forming the absolute value of value to be looked-up, determining a logarithmic offset by evaluating a position of the most significant bit of the absolute value and multiplying the position by 2 m , taking the value of the set of m bits following the most significant bit as linear offset, and in case the value to be looked-up being a negative value, providing the half number of elements of the three-dimensional look-up table reduced by a sum of the logarithmic offset and the linear offset as index value, and otherwise providing a sum of a half number of elements of the three-dimensional look-up table, the logarithmic offset and the linear offset as index value. 9. A gradient amplifier for powering a gradient coil comprising: at least two half bridges, each half bridge having at least two power switches connected in series; an output filter having inputs connected to tapped center points of the half bridges, and outputs configured to be connected to a magnetic field gradient coil; a compensation block configured to receive a desired duty cycle (a eff ), an input current (i filt ) received on the filter inputs, and a filter output voltage (Uc filt ) at the filter outputs, input the desired duty cycle (a eff ), the input current (i filt ) and the filter output voltage (Uc filt ) into a three-dimensional look-up table, and retrieve a modulator duty cycle (a mod ) from the three dimensional-look-up table; and a modulator configured to control the power switches with the modulator duty cycle (a mod ) retrieved from the three-dimensional look-up table. 10. The gradient amplifier according to claim 9 , wherein the power switch comprises a power transistor. 11. The gradient amplifier according to claim 10 , wherein the power transistor includes a MOSFET or an IGBT connected in parallel with a diode.